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Optical phenomenon

Optical phenomena encompass the observable effects arising from the interactions of with and the surrounding , including processes such as , , , , and . These events occur due to the wave-like and particle-like properties of , as described by electromagnetic theory, and are central to the field of , which examines how propagates, scatters, and is manipulated in various media. Fundamental to physics, optical phenomena explain everyday visual experiences and underpin technologies like and . In natural settings, optical phenomena are vividly displayed through atmospheric interactions, where bends, scatters, or reflects off particles like droplets or ice crystals. For instance, rainbows form when sunlight undergoes , internal , and within raindrops, producing a of colors with the primary bow exhibiting a radius of about 42 degrees. Halos, such as the common 22-degree halo around the sun or moon, result from through hexagonal ice crystals in high-altitude clouds, creating circular rings of . Mirages, optical illusions like the apparent "puddles" on hot roads, arise from caused by sharp temperature gradients in the air, which alter the and bend rays toward cooler layers. Beyond nature, optical phenomena drive numerous scientific and applications by exploiting light's behavior at interfaces and in materials. and , governed by laws like the angle of incidence equaling the angle of and (n_i \sin \theta_i = n_t \sin \theta_t), enable imaging systems such as lenses and mirrors in cameras and telescopes. patterns, observed in setups like the , reveal wave superposition and are crucial for precision measurements in and . , the bending of light around obstacles, limits resolution in optical instruments but also enables techniques like for studying atomic structures. , the orientation of light's , finds use in displays and glare-reducing , with effects like minimizing for specific polarizations. These phenomena not only illuminate fundamental principles of wave but also continue to inspire advances in and quantum technologies, where controlling light- interactions at nanoscale levels yields innovations like photonic crystals and components.

Fundamentals

Definition and Scope

Optical phenomena refer to the observable effects arising from the interactions of with , encompassing processes such as , , , , , and absorption. These manifestations are fundamentally visual or detectable within the , ultraviolet, or ranges, distinguishing them from non-optical electromagnetic interactions like those in radio waves or X-rays. The scope of optical phenomena is extensive, covering both natural occurrences—such as those in atmospheric or biological contexts—and artificial setups in laboratories or perceptual systems. Natural effects include light bending through atmospheric layers or in biological tissues, while artificial ones involve engineered devices like lenses or interferometers that exploit these principles for or . This broad purview excludes non-visual electromagnetic effects, focusing instead on 's behavior as rays, , or photons in interaction with media. Optical phenomena are classified according to underlying physical principles and environmental contexts. By principle, they fall into geometric optics (treating as rays for and ), wave optics (addressing and via electromagnetic waves), and (incorporating photon-based effects like and ). By occurrence, they are grouped into atmospheric (e.g., light interactions with air or particles) and non-atmospheric (e.g., or biological settings) categories, providing a framework for systematic study.

Historical Overview

The earliest recorded observations of optical phenomena date back to , where , in the 4th century BCE, described rainbows and halos as reflections of sunlight from droplets and atmospheric particles in his work Meteorologica. These explanations, while qualitative, marked the initial attempts to rationalize atmospheric effects through natural causes rather than mythological interpretations. Around the 2nd century CE, advanced the study of in his Optics, conducting systematic measurements of bending at interfaces between air, , and , laying foundational empirical groundwork for understanding image distortion and atmospheric bending of . During the medieval and Renaissance periods, significant progress occurred in the Islamic world, particularly with Ibn al-Haytham's (completed around 1021 CE), which detailed the pinhole camera's formation of inverted images and refuted the emission theory of vision in favor of intromission, where light rays enter the eye from objects. This comprehensive treatise influenced European scholars and shifted optics toward experimental verification of . In the 17th through 19th centuries, European scientists built on these foundations with mechanistic models. Isaac Newton's 1666 prism experiments demonstrated the dispersion of white light into a , establishing that color arises from varying refractive indices rather than modification of a single hue. proposed the wave theory of light in 1678, explaining and through secondary wavelets propagating in an . By 1801, Thomas Young's provided evidence of interference patterns, solidifying light's wave nature and challenging particle models. The 20th century introduced quantum perspectives, with Albert Einstein's 1905 explanation of the positing light as discrete quanta (photons), bridging wave and particle behaviors. emerged post-1920s through and , with seminal works by Dirac and others formalizing light-matter interactions at the quantum level. Modern milestones include the 1960 invention of the by , enabling coherent light for studying nonlinear phenomena like . From the 1980s onward, computational modeling advanced simulations of complex effects, such as and , via methods like complex ray tracing and finite-difference time-domain algorithms.

Principles of Optics

Geometric Optics

Geometric optics, also known as ray optics, approximates the behavior of light as straight-line rays propagating through space, ignoring its wave nature to model phenomena involving reflection, refraction, and image formation on macroscopic scales. This approach is particularly effective for systems where the wavelength of light is much smaller than the dimensions of optical elements, allowing for straightforward predictions of light paths using geometric constructions. The foundational principles stem from classical observations and experiments, enabling the analysis of everyday optical devices without delving into interference or diffraction effects. The law of reflection states that light rays incident on a surface obey the rule that the angle of incidence equals the angle of reflection, measured relative to the normal at the point of incidence, which holds for both plane and curved surfaces. This principle governs how mirrors produce images: specular reflection occurs on smooth surfaces like polished metal, where parallel incident rays reflect parallel to form clear virtual or real images, whereas diffuse reflection on rough surfaces scatters rays in multiple directions, preventing coherent image formation but enabling visibility of objects under illumination. For refraction, Snell's law quantifies the bending of rays at interfaces between media with different refractive indices: n_1 \sin \theta_1 = n_2 \sin \theta_2, where n is the refractive index and \theta the angle from the normal; this law, first accurately described by Ibn Sahl in 984 CE and later by Willebrord Snell in 1621, explains how light speed variations cause path deviations. Lenses manipulate to focus rays, with converging () lenses bending rays to a real and diverging () lenses spreading them to a focus; for a in air, the f is given by the lensmaker's equation \frac{1}{f} = (n-1)\left( \frac{1}{R_1} - \frac{1}{R_2} \right), where n is the of the lens material and R_1, R_2 are the radii of of its surfaces. Prisms exploit to deviate rays by an dependent on their apex and material, and basic dispersion arises because varies with wavelength—shorter wavelengths (e.g., blue) bend more than longer ones (e.g., red)—separating white light into a spectrum without requiring wave interference. In applications, these principles enable image formation in cameras, where a lens focuses rays from distant objects onto a sensor plane to create sharp inverted real images, and in the human eye, where the cornea and crystalline similarly converge rays onto the retina for inverted real images that the brain interprets upright. Total internal reflection occurs when light in a denser medium strikes a boundary at an greater than the critical (\theta_c = \sin^{-1}(n_2/n_1)), causing complete reflection; this underpins fiber optics, where cabled glass cores with cladding of lower guide signals over kilometers with minimal loss via repeated internal bounces. The in geometric holds when wavelengths are negligible compared to obstacle or sizes, accurately modeling in uniform media and interactions with large-scale elements like lenses or mirrors. However, it breaks down near edges or small openings, where causes ray spreading, necessitating wave for precise predictions in such regimes. This limitation highlights geometric as a high-frequency asymptotic to the full electromagnetic theory of .

Wave and Quantum Optics

Wave optics describes optical phenomena that arise from the wave nature of light, governed by the , which states that the resultant wave displacement at any point is the algebraic sum of the displacements from individual waves. This linear superposition enables key effects like and , which are prominent when light interacts with apertures or obstacles on scales comparable to its . Interference manifests as regions of enhanced or reduced due to the coherent overlap of . In constructive , align in , amplifying the ; in destructive , out-of- cancel, minimizing . For two coherent of equal , the resulting follows I \propto \cos^2\left(\frac{\delta}{2}\right), where \delta is the difference between the . , meanwhile, refers to the spreading of beyond geometric , explained by treating each point on a as a source of secondary wavelets. In single-slit , destructive produces minima at angles satisfying \sin \theta = \frac{m \lambda}{a}, with m = \pm 1, \pm 2, \dots, \lambda the wavelength, and a the slit width. Quantum optics extends these wave descriptions by incorporating light's particle-like duality, treating photons as discrete quanta with energy E = h \nu, where h is Planck's constant and \nu the frequency. This quantization resolved inconsistencies in classical wave theory, such as the ultraviolet catastrophe in blackbody radiation. The photoelectric effect further illustrates this: light ejects electrons from a metal surface only if its frequency exceeds a material-specific threshold, with electron kinetic energy E_k = h \nu - \phi (where \phi is the work function), independent of intensity below the threshold. Einstein's explanation unified wave and particle views, earning him the 1921 Nobel Prize. Classic experiments highlight these principles. Young's double-slit experiment (1801) passes coherent through two narrow slits, producing an interference pattern of alternating bright and dark fringes on a screen, confirming light's wave nature through superposition. causes the iridescent colors in soap bubbles, where reflects from the inner and outer soap-water interfaces, undergoing a path-length-dependent phase shift that leads to constructive interference for certain wavelengths and destructive for others, varying with film thickness. (1923) demonstrates photon's particle : X-rays scattered by loosely bound electrons in light elements exhibit a wavelength increase \Delta \lambda = \frac{h}{m_e c} (1 - \cos \theta), where m_e is , c , and \theta scattering angle, inconsistent with classical scattering but aligning with photon-electron collisions. Modern quantum optics explores non-classical effects like entanglement, where photon pairs generated via processes such as exhibit correlated polarizations that violate Bell's inequalities, as verified in Aspect's 1982 experiments using time-varying analyzers to close locality loopholes. These entangled states enable applications in quantum spectroscopy, where techniques like coherent control of atomic transitions achieve sub-Doppler resolution and precision measurements beyond classical limits, as in and frequency metrology.

Atmospheric Phenomena

Refraction-Based Effects

Refraction-based effects in the atmosphere arise from the gradual bending of light rays due to variations in air density, primarily caused by gradients in or . These gradients alter the of air, leading to optical distortions that create apparent displacements or multiple images of distant objects. Unlike abrupt at interfaces, atmospheric occurs continuously over extended paths, often spanning kilometers. Inferior mirages form when light rays from an object pass through a layer of warmer, less dense air near the ground, bending the rays upward away from the hotter region and producing an inverted image below the actual object, such as the shimmering "" seen on hot desert roads or highways. Superior mirages, in contrast, occur under temperature inversions where colder, denser air lies beneath warmer air, causing rays to bend downward and create erect or multiple images above the object, often elevating or distorting distant horizons. These effects rely on the principle of applied across varying media, as detailed in geometric optics. A prominent example of a superior mirage is the fata morgana, a complex, rapidly shifting display of stacked, distorted images resembling castles or ships, typically observed over cold water bodies like seas or lakes where strong inversions trap rays in a duct-like path. , another superior mirage variant, elevates the apparent height of distant objects such as mountains or ships, making them visible beyond the normal horizon when a steep exaggerates the downward of rays. The green flash at sunset represents a effect combined with chromatic : as the sun's upper rim dips below the horizon, the atmosphere's causes green to refract more than red , briefly isolating a green burst lasting one to two seconds under clear conditions. The of air, n, varies with atmospheric conditions according to the empirical relation (n - 1) \times 10^6 \approx 77.6 \frac{[P](/page/Pressure)}{[T](/page/Temperature)} for dry air, where P is in and T is in , reflecting the direct to air ; this leads to a change of about $10^{-6} per degree . In such gradients, rays follow curved paths with a roughly 6.6 to 7 times the Earth's radius under standard conditions, enabling the long-distance bending necessary for formation. These phenomena are prevalent in deserts, where intense surface heating drives strong inferior mirages, and in polar regions, where persistent cold layers foster superior mirages like the fata morgana. Historical accounts from explorations, such as the 1913-1917 , document mirages deceiving navigators by fabricating illusory landmasses, contributing to navigational errors in the early . Ice crystals in high-altitude clouds produce striking angular effects through their shapes, combining and to form halos and sundogs. The common appears as a white or faintly colored ring encircling or , resulting from refracting through the 60° prism faces of randomly oriented plate or column crystals, with a angle of 22° due to the crystal's (∼1.31 for at visible wavelengths). Sundogs, or parhelia, manifest as bright spots at the 's 3 o'clock and 9 o'clock positions, formed when passes through horizontal plate crystals aligned parallel to the ground, refracting at the same 22° angle and red light inward toward . These effects highlight crystals' role in particle-specific redirection, often accompanied by subtle from the geometry.

Scattering and Diffraction Effects

Scattering and diffraction effects in the atmosphere arise primarily from interactions of or with small particles such as air molecules, , and droplets, redirecting light in ways that produce vivid color shifts and angular patterns. These phenomena differ from in smooth media by involving discrete particle-induced deviations, often leading to wavelength-selective . Rayleigh and dominate for molecular and aerosol interactions, respectively, while manifests in aureole-like rings around celestial bodies. Rayleigh scattering occurs when light interacts with particles much smaller than the wavelength, such as nitrogen and oxygen molecules in the air, resulting in elastic scattering that is highly wavelength-dependent. The scattered intensity is proportional to $1/\lambda^4, where \lambda is the wavelength, making shorter blue-violet light scatter far more efficiently than longer red light—by a factor of about 10 for visible wavelengths. This explains the blue color of the daytime sky, as blue light is diffused in all directions from overhead sunlight, while at sunset, the longer path through the atmosphere scatters away shorter wavelengths, leaving predominantly red hues to reach the observer. The Rayleigh scattering cross-section for such small spherical particles is given by \sigma_s = \frac{8\pi}{3} k^4 a^6 \left| \frac{m^2 - 1}{m^2 + 2} \right|^2, where k = 2\pi / \lambda is the wave number, a is the particle radius, and m is the refractive index; for air molecules, this approximates \sigma \approx \frac{8\pi}{3} (k a)^4 a^2 times a polarizability factor, emphasizing the strong \lambda^{-4} scaling. In contrast, Mie scattering governs interactions with larger particles comparable to or exceeding the wavelength, such as , , or aerosols, producing less pronounced color dependence and a preference for forward directions. Unlike Rayleigh's isotropic yet blue-biased pattern, Mie scattering efficiency approaches the geometric cross-section \pi a^2 for large particles, with the phase function peaking sharply in the forward direction (small scattering angles) due to around the particle's silhouette, while backscattering remains weaker. This forward preference contributes to hazy skies with muted colors during dust storms or pollen seasons, as the scattering redistributes light without strong spectral selectivity, affecting visibility over broad wavelengths. Seminal work on Mie theory, applicable to atmospheric aerosols, confirms these patterns through exact solutions to for spherical scatterers. Diffraction effects become prominent when passes near uniform cloud droplets or ice particles, creating patterns that form —concentric colored rings around the sun or , typically with a of 5–10° depending on droplet size. These arise from the wave nature of bending around droplet edges, with smaller droplets (∼1–10 μm) producing larger, more colorful rings via ; blue diffracts at smaller angles than red, yielding inner blue and outer red fringes when droplets are monodisperse. The central bright region, known as the aureole, results from intense forward overlapping the direct beam. A related backscattering phenomenon is , an aureole of colored rings centered on the (e.g., around an observer's shadow on clouds), formed by near-180° and from the rear of uniform droplets, often visible from . Glories exhibit a bright white core with faint spectral rings, emphasizing the symmetry in backward for sizes near the .

Non-Atmospheric Phenomena

Everyday and Laboratory Effects

One common everyday optical phenomenon involves the formation of rainbows in water droplets from garden sprinklers or hoses. When passes through these suspended droplets, it undergoes upon entering the water, dispersing into its constituent colors due to the wavelength-dependent of water, which is approximately 1.33 for visible light. The light then reflects internally off the back surface of the droplet and refracts again upon exiting, resulting in a of colors visible to an observer positioned with behind them. Another familiar effect is the iridescent coloration observed in slicks on wet surfaces, arising from . A thin layer of , typically 100-500 thick, floats on , creating a boundary where reflects from both the air- and - interfaces. The path length difference between these reflected rays leads to constructive for certain wavelengths and destructive for others, producing shifting rainbow-like patterns that depend on the and film thickness. In laboratory settings, demonstrate in an air wedge formed between a plano-convex and a flat plate. Monochromatic incident from above reflects off both the curved surface and the flat plate below, creating an air film of varying thickness that causes fringes appearing as concentric s. For the m-th dark in reflected , the radius satisfies r_m^2 = m \lambda R, where [\lambda](/page/Lambda) is the , R is the radius of , and m is an , illustrating the direct relation between fringe spacing and . Holography provides another key laboratory example, relying on coherent to record and reconstruct three-dimensional images. A beam is split into an object beam illuminating the subject and a reference beam; the interference pattern between the scattered object wave and the reference wave is recorded on a photosensitive plate. Upon illumination with the reference beam, the plate diffracts to recreate the original , producing a hologram viewable from multiple angles without lenses. Total internal reflection is routinely observed in fiber optics, enabling light transmission over long distances in everyday applications like medical endoscopes. When light travels through the dense core glass ( ~1.46) surrounded by a lower-index cladding (~1.44), rays incident above the —calculated as \theta_c = \sin^{-1}(n_2 / n_1)—reflect entirely back into the core, preventing and allowing with minimal . Polarized sunglasses exploit Brewster's angle to reduce glare from reflective surfaces, such as roads or . At the Brewster angle, \theta_B = \tan^{-1}(n_2 / n_1), where n1 is air (~1) and n2 is the reflecting medium (e.g., ~1.5 for ), the reflected is fully polarized parallel to the surface, while the transmitted is partially polarized perpendicularly; vertical polarizers in the lenses block the horizontal glare component, enhancing visibility. Laser speckle patterns emerge in controlled environments when coherent light scatters off a rough surface, producing a granular intensity distribution due to random among the scattered wavefronts. This phenomenon, observable in laser pointers shone on walls, results from the fixed phase relationships in the coherent source, creating bright and dark spots that shift with motion but can cause visual discomfort or be used in for surface analysis. In technology, optical fibers leverage low-loss for high-speed data transmission, with silica-based single-mode fibers achieving below 0.2 dB/km at 1550 nm, primarily due to minimized and impurity absorption. This enables signals to travel hundreds of kilometers without amplification, supporting global backbones and reducing energy costs in data networks.

Entoptic and Biological Effects

Entoptic phenomena are that originate within the eye itself, arising from the of internal structures or processes rather than external light sources. These include , which appear as dark specks or threads drifting across the , caused by shadows cast on the by opacities such as cells or debris suspended in the vitreous humor. Another prominent example is the , observed when gazing at a uniform bright blue surface, where tiny bright dots move rapidly along curving paths; these represent the silhouettes of , or leukocytes, flowing through the capillaries of the , with red blood cells appearing as darker gaps between them. Specific optical effects tied to the eye's further illustrate entoptic and biological interactions with . Purkinje images, also known as Purkinje–Sanson images, are multiple reflections of a source from the eye's refractive surfaces, including the anterior (first image), posterior (second), anterior (third), and posterior (fourth); these virtual images shift relative to each other during eye movements, aiding in assessments of ocular alignment and positioning. Phosphenes, conversely, manifest as flashes of without external stimulation, often induced by mechanical pressure on the eyeball, which directly activates cells and triggers neural firing in the visual pathway, mimicking photoreceptor signals. Beyond human , biological optics in demonstrate how internal structures produce striking optical effects. in species like arises from nanoscale architectures in their wing scales, such as multilayer ridges functioning as gratings, which interfere with to create iridescent hues that shift with viewing angle, as seen in the vivid blues of Morpho butterfly wings. represents another biological optical process, where organisms generate through chemical reactions; in fireflies, the catalyzes the oxidation of in the presence of ATP and oxygen, emitting yellow-green with a peak around 550 nm from specialized abdominal organs. Certain limits of human vision also stem from biological optical constraints. The blind spot, or physiological , occurs at the where the exits the , lacking photoreceptors and thus insensitive to light, typically spanning about 5.5° horizontally and 7.5° vertically in the temporal . Afterimages, persistent visual impressions following intense stimulation, result from temporary fatigue or adaptation of photoreceptors in the ; for instance, prolonged exposure to a bright red field exhausts the red-sensitive cones (L-cones), leading to a subsequent green-tinged negative when viewing a neutral background.

Perceptual and Illusory Effects

Perceptual and illusory effects in arise when the human visual system accurately detects stimuli but misinterprets them due to cognitive , leading to systematic errors in . These illusions highlight the brain's in constructing a coherent view of the world by applying assumptions about depth, motion, and , often overriding the raw sensory input. Unlike purely physical optical phenomena, these effects stem from the interaction between sensory data and higher-level neural mechanisms, demonstrating how is an active rather than a passive recording. Geometric illusions represent a key category where spatial cues mislead size or shape judgments. The , for instance, involves two lines of equal length flanked by arrowheads pointing inward or outward, causing the outward-pointing version to appear longer due to misinterpreted depth cues that suggest one line recedes into the distance. This effect is attributed to the brain's application of perspective principles, where the fins evoke the impression of corners in a three-dimensional , prompting size scaling as if the farther line were physically larger. Motion illusions, such as the , occur when continuously rotating objects under stroboscopic lighting or discrete sampling appear to rotate backward or freeze. This arises from the visual system's temporal sampling limitations, akin to in , where the fails to capture the true motion direction, leading to ambiguous neural representations of velocity. Color and brightness illusions exploit contextual influences on luminance and hue perception. In the checker shadow illusion, two squares of identical luminance—one in shadow and one in light—appear dramatically different in brightness because the brain compensates for assumed illumination gradients, interpreting the shadowed square as lighter to maintain color constancy. Simultaneous contrast similarly alters perceived color: a gray patch adjacent to black appears lighter, while next to white it seems darker, due to the relative enhancement of differences between neighboring regions. These effects underscore how surrounding luminance modulates retinal responses, prioritizing relational judgments over absolute values. The physiological basis for many such illusions lies in early visual processing, particularly in the , where neighboring photoreceptors suppress each other's activity to sharpen edges and enhance contrast. This mechanism amplifies differences in light intensity, contributing to overestimation in brightness illusions by exaggerating boundaries between stimuli. Higher-level organization follows principles, such as proximity—which groups nearby elements as a single unit—and , which compels the brain to perceive incomplete shapes as whole figures, filling in gaps to form coherent percepts. These principles guide figure-ground segregation and pattern completion, often leading to bistable or erroneous interpretations when stimuli are ambiguous. Famous examples illustrate the potency of these effects. The , a trapezoidal chamber viewed through a , appears rectangular due to distorted cues that align walls and floor with normal room geometry, causing people at different distances to seem gigantic or dwarfed as the applies standard size-distance scaling. The , a wireframe of a , exemplifies : it spontaneously flips between two depth interpretations because neither provides unambiguous front-back cues, with alternating based on attentional shifts or . Although historically thought to vary culturally with reduced effects in non-industrialized, "non-carpentered" environments due to lack of angular depth cues in built structures, recent research as of 2025 suggests such differences are not reliably supported, likely due to methodological issues in early studies.

Anomalous Phenomena

Unexplained Aerial Lights

Unexplained aerial lights refer to recurring observations of luminous orbs or balls of light appearing in specific geographic locations, defying conventional explanations from geometric or . These phenomena, documented over decades, exhibit erratic behaviors such as hovering, pulsing, or rapid movement without identifiable sources like or celestial bodies. Unlike transient events tied to , they persist as localized anomalies, prompting ongoing scientific investigations into potential formations or geophysical triggers. The , observed in Norway's Hessdalen valley since the , manifest as pulsing, plasma-like orbs ranging from decimeters to 30 meters in diameter, displaying colors including white, red, blue, and green, with erratic trajectories and sudden brightness increases up to 19 kW. Spectral analyses have identified emissions consistent with ionized gases, predominantly and oxygen, alongside trace elements like and iron, suggesting involvement of processes. Despite radar and photographic monitoring by the Hessdalen Observatory, the lights' self-regulated clustering and short-duration pulsations (under 1 second) remain unexplained, with no consistent lines detected in broader spectra. In , the , first reported in the 1880s near Marfa, appear as glowing orbs hovering low on the horizon, often exhibiting unexplained horizontal and vertical motions that do not align with distant headlights, despite that being proposed. Observers describe the orbs as dancing or merging, visible for minutes to hours, particularly under clear skies, with no verifiable correlation to known light sources. Scientific efforts, including studies, have ruled out simple for some instances, leaving the phenomenon's origin unresolved. Australia's Min Min lights, reported in the since the , are described as traveling, fuzzy-edged orbs about one-quarter the Moon's size, following observers over distances before vanishing. Indigenous Australian folklore attributes them to ancestral spirits or elders protecting the land, with sightings tied to remote areas like Boulia and the . While some cases may involve superior mirages, many reports of independent motion and persistence challenge optical explanations, maintaining their status as an enduring mystery. Scientific scrutiny of these lights has intensified, revealing inconsistent signatures and trajectories that evade standard models, with 2020s deployments of drones and in regions like Hessdalen yielding inconclusive results due to the phenomena's intermittency. Unlike broader unidentified aerial phenomena often linked to potential craft, these focus exclusively on optical without structural evidence, emphasizing their role as geophysical or plasma-based enigmas rather than indicators.

Transient Luminous Events

Transient luminous events (TLEs) are short-lived electrical discharges that occur in the upper atmosphere, typically above active thunderstorms, manifesting as colorful optical phenomena in the , , and lower . These events are triggered by intense activity within thunderstorms, involving quasi-static or electromagnetic pulses that ionize and excite atmospheric gases, leading to luminous emissions. TLEs are distinct from conventional as they appear at altitudes ranging from 40 to over 100 , far above tops, and are often only visible under dark, clear skies from distances of 60-250 miles. The primary types of TLEs include sprites, elves, halos, blue jets, and gigantic jets, each characterized by unique morphologies and emission spectra. Sprites, the most commonly observed, appear as red, filamentary or jellyfish-like structures at 50-90 km altitude, resulting from impact of molecules producing red emissions in the 1P N₂ band. Elves manifest as expanding rings of light at 90-100 km, up to 300 km wide and lasting less than 1 millisecond, caused by electromagnetic pulses from that induce diffuse . Halos are diffuse, disk-shaped glows around 80 km, spanning 40-70 km, while blue jets originate from cloud tops at about 40 km and extend upward with blue emissions from excited ions. Gigantic jets, rarer, connect clouds directly to the at 70-90 km, combining features of sprites and jets. TLEs were first accidentally photographed on July 6, 1989, during a study of Earth's horizon from a mission, with subsequent ground-based confirmations leading to systematic observations. Space-based instruments like the Imager of Sprites and Upper Atmospheric Lightning (ISUAL) on the FORMOSAT-2 satellite have recorded thousands of events since 2004, including 5,434 elves, 633 sprites, 657 halos, and 13 gigantic jets over three years, highlighting their global prevalence above intense convective storms. Ground observations often use DSLR cameras with wide-angle lenses under dark conditions, supported by projects to catalog occurrences. Physically, TLEs involve breakdown processes such as conventional dielectric and runaway electron avalanches, sometimes producing associated terrestrial gamma-ray flashes (TGFs) with energies up to 30 MeV. They are predominantly linked to positive cloud-to-ground strokes, which redistribute charge and create transient exceeding local breakdown thresholds. Research emphasizes their role in coupling the to the upper atmosphere, influencing ionospheric dynamics and potentially contributing to global via gravity waves. Seminal studies, including Fukunishi et al. (1996) on sprite observations and Pasko et al. (1997) on excitation mechanisms, have established foundational models for TLE generation.